posted on 2016-11-18, 00:00authored byNingxiao Yuan, Lu Xu, Hualiang Wang, Youpeng Fu, Zhe Zhang, Lan Liu, Cuiling Wang, Jianhao Zhao, Jianhua Rong
Double-network (DN) hydrogels with
high strength and toughness
have been developed as promising materials. Herein, we explored a
dual physically cross-linked polyacrylamide/xanthan gum (PAM/XG) DN
hydrogel. The nonchemically cross-linked PAM/XG DN hydrogels exhibited
fracture stresses as high as 3.64 MPa (13 times higher than the pure
PAM single network hydrogel) and compressive stresses at 99% strain
of more than 50 MPa. The hydrogels could restore their original shapes
after continuously loading–unloading tensile and compressive
cyclic tests. In addition, the PAM/XG DN hydrogels demonstrated excellent
fatigue resistance, notch-insensitivity, high stability in different
harsh environments, and remarkable self-healing properties, which
might result from their distinctive physical-cross-linking structures.
The attenuated total reflectance infrared spectroscopy (ATR-IR) and
dynamic thermogravimetric analysis (TGA) results indicated that there
were no chemical bonds (only hydrogen bonds) between the XG and PAM
networks. The PAM/XG DN hydrogel synthesis offers a new avenue for
the design and construction of DN systems, broadening current research
and applications of hydrogels with excellent mechanical properties.